Effect of Amino Acids on Fusarium oxysporum Growth and Pathogenicity Regulated by TORC1-Tap42 Gene and Related Interaction Protein Analysis

Free amino acids (AAs) formed in fermented meat products are important nitrogen sources for the survival and metabolism of contaminating fungi. These AAs are mainly regulated by the TORC1-Tap42 signaling pathway. Fusarium spp., a common contaminant of fermented products, is a potential threat to food safety. Therefore, there is an urgent need to clarify the effect of different AAs on Fusarium spp. growth and metabolism. This study investigated the effect of 18 AAs on Fusarium oxysporum (Fo17) growth, sporulation, T-2 toxin (T-2) synthesis and Tri5 expression through Tap42 gene regulation. Co-immunoprecipitation and Q Exactive LC-MS/MS methods were used to detect the interacting protein of Tap42 during specific AA treatment. Tap42 positively regulated L-His, L-Ile and L-Tyr absorption for Fo17 colony growth. Acidic (L-Asp, L-Glu) and sulfur-containing (L-Cys, L-Met) AAs significantly inhibited the Fo17 growth which was not regulated by Tap42. The L-Ile and L-Pro addition significantly activated the sporulation of ΔFoTap42. L-His and L-Ser inhibited the sporulation of ΔFoTap42. In T-2 synthesis, ΔFoTap42 was increased in GYM medium, but was markedly inhibited in L-Asp and L-Glu addition groups. Dose–response experiments showed that 10–70 mg/mL of neutral AA (L-Thr) and alkaline AA (L-His) significantly increased the T-2 production and Tri5 expression of Fo17, but Tri5 expression was not activated in ΔFoTap42. Inhibition of T-2 synthesis and Tri5 expression were observed in Fo17 following the addition of 30–70 mg/mL L-Asp. KEGG enrichment pathway analysis demonstrated that interacting proteins of Tap42 were from glycerophospholipid metabolism, pentose phosphate pathway, glyoxylate and dicarboxylate metabolism, glycolysis and gluconeogenesis, and were related to the MAPK and Hippo signaling pathways. This study enhanced our understanding of AA regulation in fermented foods and its effect on Fusarium growth and metabolism, and provided insight into potential ways to control fungal contamination in high-protein fermented foods.


Chemicals and Experimental Strains
Wild-type Fusarium oxysporum (Fo17, GDMCC 60824, isolated from dried fish) has a strong T-2 toxin synthesis ability. Gene deletion strain ∆FoTap42 and complement strain ∆FoTap42-C were obtained by the double-crossover homologous recombination method (in a preliminary experiment). Top10 Escherichia coli and Rossetta (DE3) competent cells were purchased from Kamede Biological (Tianjin, China).

Colony Growth Analysis
A dextrose agar medium (20 g glucose, 20 g agar 0.1 g chloramphenicol) containing 5 mg/mL each of 18 AAs was prepared. For the control group, PDA medium was used without AA addition. The wild-type Fo17, ∆FoTap42 and ∆FoTap42-C were inoculated into a AA dextrose agar medium with a 5 mm mycelium disk, cultured for 7 d at 28 • C. The colony's morphology was observed and photographed.

Sporulation Capacity Analysis
A 1L Czapek dox agar (CDA) liquid medium (nitrogen (N) source removed, containing 1 g K 2 HPO 4 , 0.5 g KCl, 0.5 g MgSO 4 ·7H 2 O, 0.01 g FeSO 4 ·7H 2 O, 30 g saccharose) containing 10 mg/mL each of 18 AAs were prepared. The control group used a CDA liquid medium with an original nitrogen source and without AA addition. The wild-type Fo17, ∆FoTap42 and ∆FoTap42-C were inoculated into the CDA medium with a 5 mm mycelium disk, followed by shaking at 120 rpm/min at 28 • C for 7 d. Next, spores in cultured solution were dispersed with a 84-1A magnetic agitator (Sile, Shanghai, China) at a speed of 500 rpm/min and filtered with three layers of gauze. The 50 µL filtrate was transferred to a blood cellcounting plate to calculate the number of spores using a CX23 optical microscope (Puch, Shanghai, China).

T-2 Toxin-Producing Ability Analysis
A 1L GYM liquid medium (N source removed, containing 0.2 g KCl, 0.2 g MgSO 4 ·7H 2 O, 10 g glucose, 5 g yeast extract, 1 mL 0.005 g/L CuSO 4 ·5H 2 O, 1 mL 0.01 g/L ZnSO 4 ·7H 2 O) containing 5 mg/mL each of 18 AAs were prepared. The control group used a GYM liquid medium with original N source and without AA addition. A 1 mL GYM solution was added into a 2 mL centrifuge tube. Next, wild-type Fo17, ∆FoTap42 and ∆FoTap42-C were inoculated into the GYM medium with two 5 mm mycelium disks and cultured at 28 • C for 14 d. After culturing, the solution was centrifuged (Xiangyi, Changsha, China) at 5000 rpm for 10 min, the supernatant was collected, 1 mL ethyl acetate was added and the solution was mixed using a XW-80A vortex (Fudi, Fuzhou, China) for 5 min. The supernatant was collected and dried at 60 • C in N. Next, 1 mL 30% methanol was added to redissolve it; then, it was filtered with a 0.22 µm filter and T-2 was detected by LC-MS/MS. Toxin analysis was performed on a Thermo Scientific Surveyor HPLC (Thermofisher, Waltham, MA, USA)system which comprised a Surveyor MS Pump Plus, an on-line degasser and a Surveyor Autosampler Plus coupled with a Thermo TSQ Quantum Access tandem mass spectrometer equipped with an electrospray ionization (ESI) source (Thermofisher, Waltham, MA, USA). The separation was performed at 35 • C using a Hypersil GOLD column (5 µm, 100 mm × 2.1 mm) (Thermofisher, Waltham, MA, USA) at a flow rate of 0.25 mL/min. The mobile phase consisted of methanol (A) and water containing 5 mM ammonium acetate 0.1% formic acid (B), with a gradient elution program as follows: 0 min 30% A, 3.0 min 90% A, 5 min 90% A and 3 min 30% MS/MS detection was carried out using a triple quadruple mass spectrometer coupled with an electrospray ionization source operating in positive (ESI+) mode (Shimadzu, Kyoto, Japan). The ionization source parameters were set as follows: spray voltage, 4500 V; sheath gas pressure, 35 au; ion sweep gas pressure, 0 au; auxiliary gas pressure, 15 au; capillary temperature, 350 • C; tube lens offset, 118 V; skimmer offset, 0; collision energy, 1.5 eV; and collision pressure, 1.5 mTorr.

T-2 Synthesis and Tri5 Expression Dose-Response Relationship Analysis
The 50 mL GYM liquid medium (N source removed) containing 10, 30, 50 or 70 mg/mL of L-Thr, L-His and L-Asp was prepared, and the F. oxysporum Fo17, ∆FoTap42 and ∆FoTap42-C were inoculated into a 1 mL GYM medium with a 5 mm mycelium disk. Next, the samples were cultured at 28 • C and centrifuged at 120 rpm/min for 14 days. Then, the culture solution was treated as explained in Section 2.4, and T-2 was detected by LC-MS/MS. The 25-50 mg (dry weight) cultured mycelia of Fo17, ∆FoTap42 and ∆FoTap42-C were weighed and ground into powder with liquid N. Total RNA was extracted using a Spin Column Fungal Total RNA Purification Kit (Sangon Biotech, Shanghai, China). Purity and concentration were determined by a nucleic acid quantitative analyzer (Thermofisher, Waltham, MA, USA). A StarScript II First-strand cDNA Synthesis Kit (Genstar, Beijing, China) was used to transcribe RNA into cDNA. The HATri/F (5-CAGATGGAGAACtGGATGGT-3) and HATri/R (5-GCACAAGTGCCACGTGAC-3) were used as primer pairs, and the β-Tubulin/F (TTCCCCCGTCTCCACTTCTT) and β-Tubulin/R (GACGAGATCGTTCAT-GTTG) were used as the internal control gene primers. The reaction system of the qRT-PCR mixture was prepared as a 10 µL reaction (containing 5 µL 2× SYBR Green Supermix, 0.4 µL of each pair of primers (10 µM), 0.2 µL ROX Reference Dye, 1.0 µL cDNA and 3.0 µL PCR-certified water). The amplification reaction cycling procedure was as follows: 5 min at 95 • C, followed by 40 PCR cycles of 10 s at 95 • C for denaturation and 30 s at 60 • C for annealing and elongation. The melting curve analysis consisted of 3 s at 60 • C, followed by heating up to 95 • C with a ramp rate of 1 • C/3 s. If the melting curves showed a clear single peak, it meant the primers were specific. The experiment was conducted for each sample in triplicate. Based on the PCR reaction's CT value, Tri5 expression was analyzed by the 2 −∆∆Ct method.
2.6. TORC1-Tap42 Interacting Protein Analysis 2.6.1. Construction of Tap42 Expression Vector Based on the NCBI website (https://www.ncbi.nlm.nih.gov/, accessed on 27 May 2022) for the Tap42 sequence and related protein sequence, analyzed the protein signal peptide to obtain the corresponding base sequence. The Tap42 template was synthesized by chemical synthesis and cloned into a pET-28a(+) (3228 bp) expression vector by the BamHI-XhoI double enzyme digestion method. The constructed expression vector was transformed into a Top10 E. coli clone, coated on an agar plate (containing 30 µg/mL kanamycin) and cultured overnight at 37 • C. A single cloned strain with the correct sequence was selected. A 100 µL sample of Rossetta (DE3) competent cells was mixed with 10 µL pET28a(+)-TAP42 plasmid, bathed in ice for 30 min, quickly heated at 42 • C for 90 s and placed in an ice bath for 5 min. The solution was coated on LB medium (containing 50 µg/mL kanamycin) and cultured at 37 • C for 14 h. Monoclones were selected for the induction culture. The cloned strain was cultured at 37 • C for 200 mL until the OD 600 was 0.6-0.8. IPTG was added to the medium for induction at 16 • C for 24 h and centrifuged at 5000 rpm for 5 min. The supernatant was filtered by a 0.22 µm filter and then enriched by Ni column affinity chromatography.

Protein Purification by Ni Column Affinity Chromatography
A binding buffer (0.02 M Na 2 HPO 4 , 0.5 M NaCl, pH = 7.4) was used to balance the Ni column, with a flow rate of 3 mL/min. The supernatant, collected in Section 2.6.1, was purified using a AKTA purifier (Explorer 10, Cytiva, Sweden). After sample loading, in order to remove the impurities, the Ni column was washed with buffer (0.02 M NaH 2 PO 4 , pH = 7.4, 0.5 M NaCl, 20 mM 1-(p-Toluenesulfonyl) imidazole) until the UV signal returned to the baseline. Elusion buffer (0.02 M Na 2 HPO 4 , 0.5 M NaCl, 500 mM 1-(p-Toluenesulfonyl)imidazole, pH = 7.4) was used to wash the Ni column until the sample was eluted. The samples were collected for SDS-PAGE expression.

Co-Immunoprecipitation Analysis
(1) Sample treatment: The cultured mycelia were washed with precooled 0.01 M PBS 3 times and centrifuged at 12,000 rpm for 1 min each time to collect the mycelia. Liquid N was used to grind it into a powder; then, it was redissolved in 1 mL IP lysis, centrifuged at 12,000 rpm for 2 min to collect the supernatant and, finally, collected on ice. (2) Next, we prepared 100 µL Ni beads in triplicate, centrifuged them at 12,000 rpm and 4 • C for 1 min and removed the supernatant. Then, we added 800 µL IP lysate, centrifuged it at 12,000 rpm and 4 • C for 1 min and removed the supernatant. This step was repeated 3 times, and the final supernatant was resuspended in 200 µL IP lysate. (3) The 10 µg of Tap42 protein was prepared by adding it into the solution and incubating at 4 • C for 60 min, followed by dividing the solution into one tube. The sample supernatant prepared in step (1) was added to the tube, incubated at 4 • C for 1 h and centrifuged at 2000 rpm at 4 • C for 1 min to remove the supernatant. Next, 1.6 mL IP lysate was added and centrifuged at 2000 rpm 4 • C for 1 min to remove the supernatant. This step was repeated five times. (4) A 30 µL sample of 1× loading buffer was added into the sample tube and boiled at 100 • C for 10 min. Next, the sample was stored at −80 • C for further studies.

LC-MS/MS Analysis of Tap42 Interacting Proteins
The electrophoretic target band was cut, transferred into a 50 mL centrifuge tube and rinsed twice with ultrapure water; then, a mixture of 25 mM NH 4 HCO 3 and 50% acetonitrile was added to decolorize for 30 min. To the extracted discolored solution, a dehydrated solution 1 of 50% acetonitrile was added and let stand for 30 min; then, it was sucked out and the dehydrated solution 2 of absolute ethyl alcohol was added and let stand for 30 min. The target band was freeze-dried in a vacuum (Xiangyi, Changsha, China) at −20 • C for 2 h to obtain a lyophilized gel block, 50 µL reductive solution 1 was added (10 mM DTT, 25 mM NH 4 HCO 3 ) and it was left to stand in a bath at 57 • C for 1 h. Next, the solution was removed, 50 µL reductive solution 2 was added (50 mm iodoacetamide, 25 mM NH 4 HCO 3 ), it was placed at room temperature (RT) for 30 min and then the solution was removed. For 10 min, 10% ethyl alcohol was added and the solution was removed. Then, the dehydrated solution 1 was added for 30 min, it was removed and the dehydrated solution 2 was added for 30 min. The dehydrating solution 2 was removed and 10 µL enzymatic hydrolysate was added (25 mM NH 4 HCO 3 containing 0.02 µg/µL trypsin) to hydrolyze overnight at 37 • C. Next, the solution was centrifuged at 12,000 rpm for 2 min to obtain the supernatant for protein analysis. A Thermofisher QE Orbitrap high field electrostatic field orbital trap mass spectrometer (Thermofisher, Waltham, MA, USA) was used to detect the interacting proteins. The first-order spectrum scanning range was 350-1600 m/z; the second-order mass spectrometry mode was CID (Elite). A new protein library was constructed using the theoretical amylase sequence. The main search parameters were as follows: (1) immobilization modification: carbomimomethyl on Cys; (2) variable modification: oxidation on Met, acetylation on protein N-terminal; (3) allowable error of parent ion of peptide: 10 ppm; (4) allowable error of fragment ion: 0.6 Da.

Statistical Analysis
All experiments were conducted three times in parallel. The data were expressed as mean ± standard deviation (SD) and statistically analyzed by IBM SPSS statistics software (Version 26.0, BioRad, Hercules, CA, USA). Significant differences between the control and the treated fish were determined by one-way analysis of variance (ANOVA), followed by the Tukey's test to compare the control and treatment group values. A p-value of <0.05 was considered significant.

Effects of AAs on Colony Growth of F. oxysporum Regulated by Tap42
Rapamycin-sensitive TORC1 protein kinase is an important component of a conserved signal-cascading mechanism which controls cellular absorption and the response of AAs to regulate fungal growth, metabolism and pathogenicity [36]. The Tap42 gene is the key regulator to absorb and metabolize AAs for fungi. The effects of AAs on the colony morphology of Fo17, ∆FoTap42 and ∆FoTap42-C are shown in Figure 1. On PDA medium, Fo17 grew normally with several aerial hyphae, while ∆FoTap42 grew relatively slowly with fewer aerial hyphae. Colony morphology recovered to normal conditions following Tap42 supplementation. The L-His, L-Leu, L-Pro, L-Thr and L-Tyr additions as nitrogen sources significantly activated the growth of Fo17, with larger hyphal diameters but fewer mycelia in the 7-d culture. The colony was significantly smaller in ∆FoTap42, especially in the L-Try and L-Tyr media. This may be because the Tap42 target-regulated the absorption of L-Try and L-Tyr, while a lack of Tap42 decreased the response of the TORC1 pathway, which resulted in growth inhibition. In the L-Val medium, the colony of ∆FoTap42 was smaller, with radial mycelia, but recovered to the normal level in ∆FoTap42-C. Sulfurcontaining (L-Cys, L-Met) and acidic (L-Asp, L-Glu) AAs significantly inhibited the growth of Fo17, ∆FoTap42 and ∆FoTap42-C, which indicated that the absorption of these two AAs was not regulated by Tap42. Supplementation with L-Cys and L-Met resulted in less mycelial growth, while L-Asp and L-Glu caused thicker hemispherical mycelia. These results are in accordance with Shiobara et al. [26], who reported an inhibitory effect of L-Met and L-Cys on Fusarium grainei growth. Hence, S-containing AAs can be used as mycotoxin antidotes [37] and fungal inhibitors [38] because the sulfhydryl groups prevent normal fungal growth and metabolism. The L-Asp and L-Glu were not conducive to Fo17 and ∆FoTap42 growth, possibly because acidic AAs significantly decreased the pH of the medium. F. oxysporum Fo17 prefers growth at pH > 6 (unpublished data).
of Fo17, ΔFoTap42 and ΔFoTap42-C, which indicated that the absorption of these two AAs was not regulated by Tap42. Supplementation with L-Cys and L-Met resulted in less mycelial growth, while L-Asp and L-Glu caused thicker hemispherical mycelia. These results are in accordance with Shiobara et al. [26], who reported an inhibitory effect of L-Met and L-Cys on Fusarium grainei growth. Hence, S-containing AAs can be used as mycotoxin antidotes [37] and fungal inhibitors [38] because the sulfhydryl groups prevent normal fungal growth and metabolism. The L-Asp and L-Glu were not conducive to Fo17 and ΔFoTap42 growth, possibly because acidic AAs significantly decreased the pH of the medium. F. oxysporum Fo17 prefers growth at pH > 6 (unpublished data).

Effect of AAs on Spore Production and T-2 Synthesis of F. oxysporum Regulated by Tap42
The spore production and T-2 synthesis of F. oxysporum Fo17, ΔFoTap42 and ΔFoTap42-C were significantly different and regulated by AAs (Table 1). Compared to the control group (CDA medium), the spore production of Fo17 in the L-Arg, L-Lys, L-Met, L-Phe and L-Pro groups were significantly elevated (p < 0.05), especially in the L-Lys group (22.30 × 10 5 CFU/L, p < 0.05), but were decreased in the L-Asp, L-Cys, L-Gly, L-Leu, Figure 1. Colony morphology of wild-type F. oxysporum Fo17, ∆FoTap42 and ∆FoTap42-C in dextrose agar medium, supplemented with 18 amino acids cultured for 7 d at 28 • C (n = 3). Control was cultured in the PDA medium.

Effect of AAs on Spore Production and T-2 Synthesis of F. oxysporum Regulated by Tap42
The spore production and T-2 synthesis of F. oxysporum Fo17, ∆FoTap42 and ∆FoTap42-C were significantly different and regulated by AAs (Table 1). Compared to the control group (CDA medium), the spore production of Fo17 in the L-Arg, L-Lys, L-Met, L-Phe and L-Pro groups were significantly elevated (p < 0.05), especially in the L-Lys group (22.30 × 10 5 CFU/L, p < 0.05), but were decreased in the L-Asp, L-Cys, L-Gly, L-Leu, L-Thr, L-Try and L-Val groups, with values ranging from 3.14-7.50 × 10 5 CFU/L. Following Tap42 deletion, the spore production of ∆FoTap42 significantly decreased (p < 0.05) in most groups with added AAs. In contrast, L-Arg, L-Ile, L-Lys, L-Met, L-Phe and L-Pro addition significantly increased (p < 0.05) the spore production of Fo17. This was most evident in the L-Ile-and L-Pro-added groups, especially the ∆FoTap42, with values ranging from 35.80-36.26 × 10 5 CFU/L. Non-polar AAs such as L-Ile and L-Pro are generally hydrophobic, which is not conducive for the absorption of pathomycetes such as Fusarium sp.; thus, the speed of fungal growth and spore production is limited [39]. The spore production of Fusarium sp. Was positively regulated by Tap42 in both the control and most AA-added groups, except L-Asp, Gly, L-Thr and L-Val. Alfatah et al. [40] reported that, in a nutrient-dependent developmental state, Tap42-Sit4-Rrd1/Rrd2 signaled for the regulation of spore germination, while Tap42 deletion inhibited the TORC1 pathway and blocked spore germination. Therefore, a lack of Tap42 leads to inactivation of a part of TORC1 function, as well as an inability to respond to glucose and other exogenous AAs, resulting in reduced sporulation. Table 1. Effects of 18 amino acids as nitrogen sources in T-2 toxin and spore production by F. oxysporum Fo17, ∆FoTap42 and ∆FoTap42-C.

Group
Spore Concentration (10 5 CFU/L) T-2 Toxin Concentration (ng/mL) Three strains were cultured in CDA and GYM media (nitrogen removal sources) and supplemented with 18 amino acids for 14 d (n = 3). The original CDA and GYM media were the controls. Different letters (a-e) in the same column indicate significant differences (p < 0.05). Compared with Fo17, significant differences (p < 0.05) of ∆FoTap42 and ∆FoTap42-C are marked with '*' in each row.
The T-2 toxin production of Fo17 was 22.86 ng/mL in the control group (GYM medium), which increased in ∆FoTap42 (30.82 ng/mL). When supplemented with Tap42, the T-2 production returned to normal. Contrary to the spore production capacity, this result indicated that a lack of the Tap42 gene can induce T-2 synthesis of F. oxysporum. Targeted gene deletion has a significant effect on fungal metabolism, and sometimes will specifically activate other metabolism pathways. He et al. [1] reported that inactivation of TORC1-Tap42 leads to autophagy in yeast. The addition of neutral AAs, such as L-Ile, L-Leu and L-Ser, increased T-2 production of Fo17, with values reaching up to 28.49, 27.07 and 29.61 ng/mL, respectively. Similarly, L-Phe, L-Pro and L-Cys significantly activated (p < 0.05) the T-2 production in Fo17, with values up to 30.49, 30.95 and 33.64 ng/mL, respectively (p < 0.05). However, acidic AAs L-Asp and L-Glu, as N sources, significantly decreased (p < 0.05) the T-2 toxin-production in Fo17 to 14.87 and 12.64 ng/mL, respectively (p < 0.05). After Tap42 deletion, the T-2 production was significantly decreased (p < 0.05) to 6.68 and 2.09 ng/mL. Thus, acidic AAs were not conducive to F. oxysporum growth and secondary metabolism, and sporulation was the main path to survival. However, the inhibition of toxin production does not mean toxicity reduction. When pathogenic fungi are exposed to pH stress, AAs are used for biotransformation and to drive environmental alkalinization for growth. Candida albicans uses AAs as the sole N source to raise the environmental pH from 4 to neutral within 6-8 h, which is another critical pathogenicity trait [41].
Compared with Fo17, the T-2-producing capacity of ∆FoTap42 was significantly increased (p < 0.05) by L-His and L-Val addition, which indicates that Tap42 negatively regulates L-His and L-Val absorption. The L-Asp and L-Glu addition significantly inhibited the T-2 synthesis by ∆FoTap42 to only 6.68 and 2.09 ng T-2/mL, respectively (p < 0.05). L-Ala, L-Arg, L-Cys, Gly, L-Leu, L-Pro, L-Ser, L-Thr and L-Try addition as N sources also reduced the T-2 production by ∆FoTap42, which may be due to a lack of AA absorption and metabolism by the corresponding pathway gene (Tap42), resulting in a decline in T-2 production. A similar result was reported by Phasha et al. [42], who similarly demonstrated that the Ras2 gene can control growth and toxin synthesis of F. circinatum though encoding mitogen-activated protein kinase.
As shown in Figure 2, heat map analysis showed the effect patterns of AAs on sporulation and T-2 production by Fo17, ∆FoTap42 and ∆FoTap42-C. During sporulation, L-Ile and L-Pro groups clustered closely together, showing significantly activated (p < 0.05) spore production of ∆FoTap42, but a reduction in ∆FoTap42-C, which indicates that Tap42 negatively regulated L-Ile and L-Pro absorption and, thereby, affected the F. oxysporum spore formation. In contrast, in the L-His and L-Ser groups, the spore production of ∆FoTap42 was lower than in Fo17 and ∆FoTap42-C, meaning that Tap42 positively activated L-His and L-Ser absorption in F. oxysporum. When a lack of a regulated gene markedly reduces spore production, it indicates a decrease in reproductive dispersal capacity. The L-Ala group clustered with the control group means that L-Ala addition did not significantly affect the spore production of Fo17, ∆FoTap42 or ∆FoTap42-C (Figure 2A). L-Asp and L-Glu addition inhibited T-2 production by Fo17, and a lack of Tap42 significantly inhibited the T-2 production (<20 ng/mL). This is because acidic AAs negatively regulated the pathogenicity of Fusarium spp.. The L-His, L-Val, L-Lys and L-Met groups clustered together, and the T-2 production was significantly increased when Tap42 was lacking ( Figure 2B).  and ΔFoTap42-C exposed to 18 amino acids as nitrogen sources (n = 3). Control was cultu and GYM media.

Dose-Effect Relationship between L-Thr, L-His and L-Asp on T-2 Toxin Synthes oxysporum Regulated by Tap42
Tri5 is the initiating gene of trichothecene synthesis, and plays an import Fusarium spp. pathogenicity [43]. In this study, neutral (L-Thr), basic (L-His) (L-Asp) AAs were selected to assess the effect on T-2 synthesis and Tri5 expr creasing L-Thr in the GYM medium significantly activated the T-2 productio  and ∆FoTap42-C exposed to 18 amino acids as nitrogen sources (n = 3). Control was cultured in CDA and GYM media.

Dose-Effect Relationship between L-Thr, L-His and L-Asp on T-2 Toxin Synthesis by F. oxysporum Regulated by Tap42
Tri5 is the initiating gene of trichothecene synthesis, and plays an important role in Fusarium spp. pathogenicity [43]. In this study, neutral (L-Thr), basic (L-His) and acidic (L-Asp) AAs were selected to assess the effect on T-2 synthesis and Tri5 expression. Increasing L-Thr in the GYM medium significantly activated the T-2 production of Fo17, ∆FoTap42 and ∆FoTap42-C (p < 0.05) with the concentrations of T-2 at 70 mg/mL L-Thr, 13.86, 16.87 and 13.85 ng/mL, respectively. Compared with the control group, a significant increase (p < 0.05) in Tri5's expression of Fo17 was observed in the 50-70 mg/mL L-Thr groups. ∆FoTap42 showed a marked activation of Tri5 expression in the 10-70 mg/mL L-Thr groups. When complemented with the Tap42 gene, the Tri5 expression was significantly increased (p < 0.05), but only in the 70 mg/mL L-Thr group ( Figure 3A). Similarly, 10-70 mg/mL L-His addition significantly increased (p < 0.05) the T-2 production of Fo17, ∆FoTap42 and ∆FoTap42-C, with the T-2 concentrations reaching 33.03, 31.66 and 32.75 ng/mL, respectively, in the 70 mg/mL L-His added group. However, the Tri5 expression of Fo17 increased, but the increase in amplitude of ∆FoTap42 and ∆FoTap42-C were lower than in Fo17 ( Figure 3B). In the L-His group, higher T-2 production and lower Tri5 expression were observed in ∆FoTap42, which may due to the lack of the TORC1-Tap42 gene, thus reducing the sensitivity to L-His and, therefore, reducing Tri5 signal transduction. However, T-2 synthesis is not only regulated by Tri5. Multiple trichothecene synthetic gene clusters, such as three P450 oxygenase genes, Tri4, Tri11 and Tri13 [44]; esterase gene Tri8 [45]; and acetyltransferase genes Tri3 and Tri7 [46] also affect T-2 synthesis. Conversely, 10 mg/mL L-Asp addition significantly increased (p < 0.05) T-2 production and Tri5 expression, while L-Asp addition gradually reduced T-2 production and Tri5 expression in Fo17, ∆FoTap42 and ∆FoTap42-C, which indicated that a low dosage of L-Asp led to a significant increase in the growth and T-2 production of F. oxysporum, whereas a high dosage reduced this effect. An inhibitory effect of Tri5 expression was detected in ∆FoTap42 following the addition of 70 mg/mL L-Asp. Thus, acidic AA L-Asp showed a significant reduction in Fusarium sp. growth and metabolism at a relatively high dose ( Figure 3C). The inhibitory effect of L-Asp has been well-studied and applied for fungal inhibition in food products. Bitu et al. [47] used L-Asp combined with Th (IV) and Zr (IV) ions to synthesize new peroxo complexes, and demonstrated high antibacterial activity in Aspergillusflavus, Penicillium sp., Candida sp. and Aspergillus niger. Thus, based on its excellent antifungal properties, L-Asp can be used as an additive in the development of natural preservatives.

L-Thr, L-His and L-Asp Activated Tap42 Interacting Proteins and Metabolic Pathways
A Tap42 expression vector was constructed using BamHi-XhoI restriction enzyme digestion. Two bands (3359 bp and 5192 bp) were observed in the pET-28a (+) plasmid vector after PCR amplification, indicating that the target gene, Tap42, was cloned into the expression vector ( Figure 4A). Through comparative analysis, the pET28a(+)-Tap42 expression vector was found to be~140 kDa. E. oil was transformed with the correctly identified positive clone plasmid, and single bacterial colonies were selected for induction expression. The results of SDS-PAGE electrophoresis are shown in Figure 4B. The recombinant strain induced by IPTG showed a fusion protein, pET28a(+)-Tap42, with a target band of~140 kDa (electrophoretic band 2-4), but not the non-induced strain (electrophoretic band 1). A purified protein (~140 kDa) was obtained after washing and eluting the protein (electrophoretic band 3) ( Figure 4C). Based on SDS-PAGE, no significant interacting proteins of Fo17 were detected in the GYM medium (electrophoretic band 1). In the L-His group, clear protein bands were detected at~10 and 39-43 kDa (electrophoretic band 2). In the L-Thr group, as well, clear protein bands were evident at~10, 27 and 39-52 kDa (electrophoretic band 3). In the L-Asp group, bands were found at~10, 27 and 39-52 kDa (electrophoretic band 4) ( Figure 4D).   phoretic band 3) ( Figure 4C). Based on SDS-PAGE, no significant interacting proteins of Fo17 were detected in the GYM medium (electrophoretic band 1). In the L-His group, clear protein bands were detected at ~10 and 39-43 kDa (electrophoretic band 2). In the L-Thr group, as well, clear protein bands were evident at ~10, 27 and 39-52 kDa (electrophoretic band 3). In the L-Asp group, bands were found at ~10, 27 and 39-52 kDa (electrophoretic band 4) ( Figure 4D). Tap42 treatment after L-Thr, L-His and L-Asp treatments were mostly DNA topoisomerase 2, glyceraldehyde-3-phosphate dehydrogenase 2, heat shock 70 kDa protein, elongation factor 1-alpha, actin, plasma membrane ATPase, enolase, transaldolase and ATP-dependent RNA helicase and citrate synthase ( Table 2). Comparative analysis showed that the L-His and L-Asp groups specifically activated the ribosome-associated molecular chaperone SSB1, regulated by SSB1, and phosphoglycerate kinase regulated by pgkA, respectively. In the L-Thr and L-His groups, pyruvate decarboxylase regulated by pdcA was markedly activated. L-His specifically activated the Tubulin alpha-B chain regulated by By Q Exactive LC-MS/MS analysis, 172, 201 and 89 potential interacting proteins of Tap42 were detected in the L-Thr, L-His and L-Asp treatment groups, respectively. A total of 86 interacting proteins co-existed in the three treatment groups. In the L-Thr and L-His groups, 84 similar interacting proteins were detected. However, only 1 and 2 interacting proteins from the L-Thr and L-His groups were similar to those observed in the L-Asp group ( Figure 5). Based on mass analysis, the common potential interacting proteins with Tap42 treatment after L-Thr, L-His and L-Asp treatments were mostly DNA topoisomerase 2, glyceraldehyde-3-phosphate dehydrogenase 2, heat shock 70 kDa protein, elongation factor 1-alpha, actin, plasma membrane ATPase, enolase, transaldolase and ATP-dependent RNA helicase and citrate synthase ( Table 2). Comparative analysis showed that the L-His and L-Asp groups specifically activated the ribosome-associated molecular chaperone SSB1, regulated by SSB1, and phosphoglycerate kinase regulated by pgkA, respectively. In the L-Thr and L-His groups, pyruvate decarboxylase regulated by pdcA was markedly activated. L-His specifically activated the Tubulin alpha-B chain regulated by tba-2 (Table 3). DNA topoisomerases were the enzymes mostly responsible for the encapsulation of double-helix DNA and the transcription of proteins, and were shown to play an important role in the growth and metabolism of fungi [48]. Candida albicans and Aspergillus niger have high levels of both type I and type II topoisomerases, and increase pathogenicity by converting cellular proteins [49]. Therefore, the inhibition of DNA topoisomerases activity is also an important target of antifungal drugs [50]. Glyceraldehyde 3-phosphate dehydrogenase is an enzymatic protein highly related to the catalyzation of oxidation (dehydrogenation) and phosphorylation of glyceraldehyde 3-phosphate to generate 1, 3-diphosphate glyceric acid, which is the central link to the glycolytic pathway and, hence, plays an important role in glycometabolism [43]. In addition, Tap42-related enolase and pyruvate decarboxylase are important enzymes in the glycolytic pathway, and play important roles in maintaining cell wall protection and fungal pathogenicity [51]. The interaction of Tap42 with these enzymatic proteins cultured in GYM medium indicates that the growth and metabolism of Fusarium firstly utilize glucose through the glycolytic pathway to acquire energy. erate 1, 3-diphosphate glyceric acid, which is the central link to the glycolytic pathway and, hence, plays an important role in glycometabolism [43]. In addition, Tap42-related enolase and pyruvate decarboxylase are important enzymes in the glycolytic pathway, and play important roles in maintaining cell wall protection and fungal pathogenicity [51]. The interaction of Tap42 with these enzymatic proteins cultured in GYM medium indicates that the growth and metabolism of Fusarium firstly utilize glucose through the glycolytic pathway to acquire energy.     The Tap42 potential interacting proteins of F. oxysporum, cultured in GYM medium, with L-threonine (L-Thr), L-Histidine (L-His) and L-Aspartic acid (L-Asp) (n = 3). A high score indicates that the protein is closely related to Tap42. The Tap42 potential interacting proteins of F. oxysporum cultured in GYM medium with L-threonine (L-Thr), L-Histidine (L-His) and L-Aspartic acid (L-Asp) addition (n = 3). A high score indicates that the protein is closely related to Tap42.
According to KEGG enrichment analysis, Tap42-interacting proteins were mostly derived from metabolism, genetic information processing, cellular processes and environmental information processing. Most of the interacting proteins came from the metabolic pathways, mainly from glycerophospholipid metabolism, pentose phosphate pathway, glyoxylate and dicarboxylate metabolism, glycolysis, gluconeogenesis, methane metabolism and glutathione metabolism. The related secondary metabolic pathways were galactose metabolism, fatty acid biosynthesis, fatty acid degradation, steroid biosynthesis, phenylalanine metabolism, one carbon pool by folate, citrate cycle, TCA cycle and oxidative phosphorylation ( Figure 6).
KEGG enrichment analysis showed that the proteins potentially interacting with Tap42 were from the mitogen-activated protein kinase (MAPK) signaling pathway and Hippo signaling pathway. The MAPK signaling pathway is composed of mitogen-activated protein kinase, which is involved in the intracellular signal regulation system and can be activated by different extracellular stimuli, such as cytokine neurotransmitter hormones, cell stress and cell adhesion [52,53]. Many reports have shown that the MAPK pathway is significantly associated with the regulation of the TORC1 pathway [54]. The Hippo signaling pathway mainly inhibits cell growth and regulates cell proliferation, apoptosis and stem cell self-renewal [55]. Recent studies have shown that the Hippo signaling pathway is closely related to cancer genesis, tissue regeneration and stem cell function regulation [56]. Identification of the associated signaling pathway provides a theoretical basis for the further exploration of the interaction network of Fusarium pathogenicity when exposed to different amino acid conditions, and also provides important information for the further control of fungal contamination in high-protein fermented foods. tose metabolism, fatty acid biosynthesis, fatty acid degradation, steroid biosynthesis, ph nylalanine metabolism, one carbon pool by folate, citrate cycle, TCA cycle and oxidat phosphorylation ( Figure 6). KEGG enrichment analysis showed that the proteins potentially interacting w Tap42 were from the mitogen-activated protein kinase (MAPK) signaling pathway a Hippo signaling pathway. The MAPK signaling pathway is composed of mitogen-ac vated protein kinase, which is involved in the intracellular signal regulation system a can be activated by different extracellular stimuli, such as cytokine neurotransmitter h mones, cell stress and cell adhesion [52,53]. Many reports have shown that the MA pathway is significantly associated with the regulation of the TORC1 pathway [54]. T Hippo signaling pathway mainly inhibits cell growth and regulates cell proliferatio apoptosis and stem cell self-renewal [55]. Recent studies have shown that the Hippo s naling pathway is closely related to cancer genesis, tissue regeneration and stem cell fu tion regulation [56]. Identification of the associated signaling pathway provides a theor ical basis for the further exploration of the interaction network of Fusarium pathogenic when exposed to different amino acid conditions, and also provides important inf mation for the further control of fungal contamination in high-protein fermented food

Conclusions
Exposure to free AAs (as N sources) showed a significant effect on the growth a metabolism of F. oxysporum regulated by Tap42. The absorption of L-Ile and L-Tyr w regulated by Tap42. Acidic (L-Asp, L-Glu) and S-containing (L-Cys, L-Met) AAs were n conducive to F. oxysporum growth, and were not regulated by Tap42. The addition of Land L-Pro activated sporulation in ΔFoTap42, but this was negatively regulated by Tap while L-His and L-Ser inhibited sporulation in ΔFoTap42, which was positively regulat by Tap42. Acidic AA showed a remarkable inhibitory effect on T-2 toxin production po tively regulated by Tap42. Neutral (L-Thr) and alkaline (L-His) AAs significantly activat the T-2 synthesis and Tri5 expression of Fusarium, while L-Asp showed an inhibitory eff

Conclusions
Exposure to free AAs (as N sources) showed a significant effect on the growth and metabolism of F. oxysporum regulated by Tap42. The absorption of L-Ile and L-Tyr was regulated by Tap42. Acidic (L-Asp, L-Glu) and S-containing (L-Cys, L-Met) AAs were not conducive to F. oxysporum growth, and were not regulated by Tap42. The addition of L-Ile and L-Pro activated sporulation in ∆FoTap42, but this was negatively regulated by Tap42, while L-His and L-Ser inhibited sporulation in ∆FoTap42, which was positively regulated by Tap42. Acidic AA showed a remarkable inhibitory effect on T-2 toxin production positively regulated by Tap42. Neutral (L-Thr) and alkaline (L-His) AAs significantly activated the T-2 synthesis and Tri5 expression of Fusarium, while L-Asp showed an inhibitory effect at relatively high doses. The co-immunoprecipitation analysis showed that the interacting proteins of Tap42 were activated by L-The, L-His and L-Asp control metabolism; genetic information processing; cellular processes and environmental information processing. L-Asp inhibited the effects on Fusarium spp. growth and metabolism, and, thus, could be used as an inhibitor to further control fungal contamination in fermented foods.  Data Availability Statement: All related data and methods are presented in this paper. Additional inquiries should be addressed to the corresponding author.